Monday, August 15, 2016

GENETICS: A BRIEF ACCOUNT





In 1860s an Austrian scientist named Gregor Mendel, while experimenting with pea plants, discovered how traits are transmitted from parents to offspring. This discovery laid the foundation for modern genetics, the study of genes and their role in inheritance.

The three major macro-molecules essential for all known forms of life are Nucleic Acids, proteins and carbohydrates. A gene is the basic unit of heredity information located in the chromosome of the nucleus of the cell. A chromosome consists of a long strand of DNA containing many genes. Genes are made up of deoxyribonucleic acid (DNA) which stores genetic information and encodes (carries) the instructions for proteins that direct the activities of cells and functions of the body. Most DNA molecules consist of two strands coiled around each other to form a double helix. Ribonucleic Acid (RNA) is similar to DNA but it is single stranded and transfers the genetic information obtained from DNA to the proper location for protein synthesis.

Genes control how a cell functions, including how quickly it grows, how often it divides, and how long it lives. To control these functions, genes produce proteins that perform specific tasks and act as messengers for the cell. That’s why it is essential that each gene have the correct instructions or “code” for making its protein so that the protein can perform the proper function for the cell. There are approximately 20,000 to 25,000 genes in each person’s genetic makeup, or genome. Every cell in a person’s body has the same DNA. If all of the DNA in our body were connected, it would stretch about 67 billion miles! Genes direct cells to make proteins and guide almost every aspect of operation and repair of cells.

A person’s genes can have a profound impact on health and disease. More than 4000 diseases are thought to be related to altered genes. Genomics is the study of all of a person’s genes (the genome), including interactions of these genes with each other and with the person’s environment. Genomic factors play a role in the leading causes of death in the United States including heart disease, cancer, diabetes mellitus, stroke, and Alzheimer’s disease. These diseases are typically caused by a combination of genetic and environmental factors.

Any change in the usual DNA sequence is called a mutation. Subtle or simple variations in DNA are called polymorphisms (many forms) which account for slight variations among people such as hair and eye color. However, some gene variations may result in disease or an increased risk for disease. The change in gene structure may alter the type and/or the amount of protein produced. 

Genetic mutation can be inherited or can occur during cell division, DNA replication, and from environmental factors like UV radiations leading to skin cancer. Toxins in cigarettes, and also in chemotherapy which also targets the healthy cells. Cells have built-in mechanisms that catch and repair most of the changes that may happen but as we age the DNA repair does not work as before and changes accumulate.

Genetic disorders can be prevented or treated by gene therapy approaches which include but may not be limited to the following:


Replacing a mutated gene with healthy copy of the gene.
Inactivating a mutated gene that is functioning improperly
Introducing a new gene into the body to help fight a disease through a viral vector
Stem cell therapy which allows for regeneration of lost tissue and restoration of function in various diseases.


CRISPER/Cas9 and targeted gene editing is now widely used in different cell types and organisms and has potential applications in human gene therapy.
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Sources

Sharon L. Lewis, et al.
Pathophysiologic Mechanisms of Disease
Genetics and Genomics 2014

Genetic-Science-The Guardian
Nicola Davis
New research about Alzheimer’s Disease 2016

Wikipedia


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